Older and young adults' letter detection and lexical decision performance were examined as word frequency varied to determine whether there were age differences in word recognition. Allen and Madden (1989) found that older adults' pattern of reaction time (RT) across word frequency categories was different from young adults' pattern for a letter detection task. In this study, for both letter detection and lexical decision tasks, older adults exhibited a monotonically decreasing RT function as word frequency increased. However, young adults exhibited a nonmonotonic RT function across word frequency for the letter detection task but a monotonically decreasing RT function as word frequency increased for the lexical decision task. An expanded parallel input serial analysis model of word processing was hypothesized.
We examined adult age differences in the impact of redundancy and perceptual noise during visual search. Using a two-choice, visual search task, subjects responded to letters presented in one to four corners of an imaginary display square. On each trial, one, two, or three instances of a given target letter were presented. In the target-plus-noise condition, all nontarget corners of the imaginary square were filled with distractor (i.e., noise) letters. In the target-only condition, all nontarget corners were left blank. The results indicated that older adults showed relatively greater redundancy benefits than the young adults for the target-plus-noise trials than for the target-only trials. These results are interpreted within an internal noise framework.
We tested healthy young and older adults as well as higher-scoring (Mini-Mental State Exam, MMSE, scores between 14-20) and lower-scoring patients diagnosed with probable Alzheimer's disease (AD) on a letter-matching task. Subjects were instructed to respond "same" if two simultaneously presented letters were identical, or "different" if the letters did not match. Healthy older adults showed a larger "fast-same" effect than healthy young adults. Also, higher-scoring AD patients showed a large "false-different" effect for errors, but lower-scoring AD patients showed a large "false-same" effect. These data indicate that older adults exhibit higher neural noise levels than younger adults. The cross-over error pattern for AD suggests that moderately demented AD patients show evidence of forming degraded visual percepts whereas more severely demented AD patients show evidence of forming incomplete percepts.
We tested young, middle-aged, and older adults for ability to organize six-letter sequences when these subjects were not externally induced to chunk the letter sets. In order to determine whether subjects would use optimal chunk sizes of two, three, or six letters, a serial recall task on which subjects were cued using digits was employed. From these data, the total number of correctly recalled sequences was computed, in addition to global and stop transitional error probabilities (TEPs). The results indicated that older adults recalled fewer correct sequences than did the young adults. However, both the global and stop TEP analyses demonstrated that all three age groups were chunking the six-letter sequences into two sets of three letters each. The present study (along with Allen & Coyne, 1988a, 1989) suggests that there are no appreciable age differences in functional chunk capacity, but that older adults exhibit poorer serial recall than younger adults.
Older and young adults' letter search performances were examined on a short-term memory (STM) task where subjects compared a five-letter target sequence stored in short-term memory to a subsequently presented five-letter probe sequence. The same five letters were always presented on target and probe portions of a given trial, but on half of the trials, two letters were transposed in the first chunk, second chunk, or between the first and second chunks of the probe sequence ("No" trials). On the remaining half of the trials, the target and probe sequences were identical ("Yes" trials). Both young and older adults showed increases in reaction time (RT) when the chunk boundary for "yes" trials was different for the target and probe sequences of a given trial. This finding indicated that both age groups were organizing the sequences in STM in the same qualitative manner. However, older adults showed a relatively greater increase in RT and errors than young adults for second-chunk transpositions than for first-chunk or between-chunk transpositions, and this finding suggested that an age difference in task complexity could not account for this effect. We propose, though, that these data are consistent with an internal noise model.
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